JIB-04, a specific inhibitor of the O2-activating, Fe-dependent histone lysine demethylases, is revealed to disrupt the binding of O2 in KDM4A/JMJD2A through a continuous O2-consumption assay, X-ray crystal structure data, and molecular docking.

The symbiosis between rhizobial microbes and host plants involves the coordinated expression of multiple genes, which leads to nodule formation and nitrogen fixation. As part of the transcriptional machinery for nodulation and symbiosis across a range of Rhizobium, NolR serves as a global regulatory protein. Here, we present the X-ray crystal structures of NolR in the unliganded form and complexed with two different 22-base pair (bp) double-stranded operator sequences (oligos AT and AA). Structural and biochemical analysis of NolR reveals protein–DNA interactions with an asymmetric operator site and defines a mechanism for conformational switching of a key residue (Gln56) to accommodate variation in target DNA sequences from diverse rhizobial genes for nodulation and symbiosis. This conformational switching alters the energetic contributions to DNA binding without changes in affinity for the target sequence. Two possible models for the role of NolR in the regulation of different nodulation and symbiosis genes are proposed. To our knowledge, these studies provide the first structural insight on the regulation of genes involved in the agriculturally and ecologically important symbiosis of microbes and plants that leads to nodule formation and nitrogen fixation.

Covering: 1966 to 2012 Sulfur is an essential element that must be assimilated by all organisms; however, the metabolic pathways for this task vary significantly, even among individual genera of bacteria, and especially so among eukaryotes. While all organisms require sulfurous amino acids, plants require specialized sulfur-containing metabolites, such as glucosinolates and allylsulfur compounds, for protection from herbivory and microbial infection; and the synthesis of specialized peptides (i.e., glutathione and phytochelatins) for protection against reactive oxygen species and exposure to transition metals, such as cadmium. In order to provide the complex array of sulfur-containing metabolites essential to plant viability, flux through the sulfur assimilatory pathway must be tightly regulated by controlling enzymatic activity. The X-ray crystal structures of several primary sulfur assimilatory enzymes, complemented by kinetics, have revealed mechanisms of enzymatic regulation (i.e., via redox state and protein–protein interaction) in these biosynthetic pathways, in addition to the chemical mechanisms of catalysis. This review summarizes the state of our structural knowledge of primary and secondary sulfur assimilatory enzymes from plants.

Phosphoethanolamine N-methyltransferase (PMT) is essential for phospholipid biogenesis in the malarial parasite Plasmodium falciparum. PfPMT catalyzes the triple methylation of phosphoethanolamine to produce phosphocholine, which is then used for phosphatidylcholine synthesis. Here we describe the 2.0 Å resolution X-ray crystal structure of PfPMT in complex with amodiaquine. To better characterize inhibition of PfPMT by amodiaquine, we determined the IC50 values of a series of aminoquinolines using a direct radiochemical assay. Both structural and functional analyses provide a possible approach for the development of new small molecule inhibitors of PfPMT.

•Structural biology studies refined the auxin response pathway.•The TIR1 E3 ubiquitin ligase structure reveals the auxin perception mechanism.•ARF DNA binding domain structures establish the ‘molecular calipers’ mechanism.•ARF and Aux/IAA PB1 interaction domain structures increase pathway complexity.Auxin is a key regulator of plant growth and development. Classical molecular and genetic techniques employed over the past 20 years identified the major players in auxin-mediated gene expression and suggest a canonical auxin response pathway. In recent years, structural and biophysical studies clarified the molecular details of auxin perception, the recognition of DNA by auxin transcription factors, and the interaction of auxin transcription factors with repressor proteins. These studies refine the auxin signal transduction model and raise new questions that increase the complexity of auxin signaling.Download high-res image (196KB)Download full-size image

JIB-04, a specific inhibitor of the O2-activating, Fe-dependent histone lysine demethylases, is revealed to disrupt the binding of O2 in KDM4A/JMJD2A through a continuous O2-consumption assay, X-ray crystal structure data, and molecular docking.